Decomposing convolution operation in neural networks

ABSTRACT

A method of operating a neural network includes determining a complexity, such as a number) of separable filters approximating a filter. The method further includes selectively applying a decomposed convolution to the filter based on the determined number of separable filters.

CROSS-REFERENCE TO RELATED APPLICATION

The present application claims the benefit of U.S. Provisional Patent Application No. 62/025,406, filed on Jul. 16, 2014, and titled “DECOMPOSING CONVOLUTION OPERATION IN NEURAL NETWORKS,” the disclosure of which is expressly incorporated by reference herein in its entirety.

BACKGROUND

1. Field

Certain aspects of the present disclosure generally relate to neural system engineering and, more particularly, to systems and methods for training and operating a neural network using decomposed convolution operations.

2. Background

An artificial neural network, which may comprise an interconnected group of artificial neurons (i.e., neuron models), is a computational device or represents a method to be performed by a computational device. Artificial neural networks may have corresponding structure and/or function in biological neural networks. However, artificial neural networks may provide innovative and useful computational techniques for certain applications in which traditional computational techniques are cumbersome, impractical, or inadequate. Because artificial neural networks can infer a function from observations, such networks are particularly useful in applications where the complexity of the task or data makes the design of the function by conventional techniques burdensome.

SUMMARY

In an aspect of the present disclosure, a method of operating a neural network is presented. The method includes determining a complexity of separable filters approximating a filter in the neural network. The method further includes selectively applying a decomposed convolution to the filter based on the determined number of separable filters.

In another aspect of the present disclosure, an apparatus for operating a neural network is presented. The apparatus includes a memory and one or more processors coupled to the memory. The processor(s) is(are) configured to determine a complexity of separable filters approximating a filter in the neural network. The processor(s) is(are) further configured to selectively apply a decomposed convolution to the filter based on the determined number of separable filters.

In yet another aspect of the present disclosure, an apparatus for operating a neural network is presented. The apparatus includes means for determining a complexity of separable filters approximating a filter in the neural network. The apparatus further includes means for selectively applying a decomposed convolution to the filter based on the determined number of separable filters.

In still another aspect of the present disclosure, a computer program product for operating a neural network is presented. The computer program product includes a non-transitory computer readable medium having encoded thereon program code. The program code includes program code to determine a complexity of separable filters approximating a filter in the neural network. The program code further includes program code to selectively apply a decomposed convolution to the filter based on the determined number of separable filters.

This has outlined, rather broadly, the features and technical advantages of the present disclosure in order that the detailed description that follows may be better understood. Additional features and advantages of the disclosure will be described below. It should be appreciated by those skilled in the art that this disclosure may be readily utilized as a basis for modifying or designing other structures for carrying out the same purposes of the present disclosure. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the teachings of the disclosure as set forth in the appended claims. The novel features, which are believed to be characteristic of the disclosure, both as to its organization and method of operation, together with further objects and advantages, will be better understood from the following description when considered in connection with the accompanying figures. It is to be expressly understood, however, that each of the figures is provided for the purpose of illustration and description only and is not intended as a definition of the limits of the present disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

The features, nature, and advantages of the present disclosure will become more apparent from the detailed description set forth below when taken in conjunction with the drawings in which like reference characters identify correspondingly throughout.

FIG. 1 illustrates an example network of neurons in accordance with certain aspects of the present disclosure.

FIG. 2 illustrates an example of a processing unit (neuron) of a computational network (neural system or neural network) in accordance with certain aspects of the present disclosure.

FIG. 3 illustrates an example of spike-timing dependent plasticity (STDP) curve in accordance with certain aspects of the present disclosure.

FIG. 4 illustrates an example of a positive regime and a negative regime for defining behavior of a neuron model in accordance with certain aspects of the present disclosure.

FIG. 5 illustrates an example implementation of designing a neural network using a general-purpose processor in accordance with certain aspects of the present disclosure.

FIG. 6 illustrates an example implementation of designing a neural network where a memory may be interfaced with individual distributed processing units in accordance with certain aspects of the present disclosure.

FIG. 7 illustrates an example implementation of designing a neural network based on distributed memories and distributed processing units in accordance with certain aspects of the present disclosure.

FIG. 8 illustrates an example implementation of a neural network in accordance with certain aspects of the present disclosure.

FIG. 9 is a flow diagram illustrating a method for operating a neural network in accordance with aspects of the present disclosure.

FIG. 10 is a flow diagram illustrating a method for training a neural network in accordance with aspects of the present disclosure.

DETAILED DESCRIPTION

The detailed description set forth below, in connection with the appended drawings, is intended as a description of various configurations and is not intended to represent the only configurations in which the concepts described herein may be practiced. The detailed description includes specific details for the purpose of providing a thorough understanding of the various concepts. However, it will be apparent to those skilled in the art that these concepts may be practiced without these specific details. In some instances, well-known structures and components are shown in block diagram form in order to avoid obscuring such concepts.

Based on the teachings, one skilled in the art should appreciate that the scope of the disclosure is intended to cover any aspect of the disclosure, whether implemented independently of or combined with any other aspect of the disclosure. For example, an apparatus may be implemented or a method may be practiced using any number of the aspects set forth. In addition, the scope of the disclosure is intended to cover such an apparatus or method practiced using other structure, functionality, or structure and functionality in addition to or other than the various aspects of the disclosure set forth. It should be understood that any aspect of the disclosure disclosed may be embodied by one or more elements of a claim.

The word “exemplary” is used herein to mean “serving as an example, instance, or illustration.” Any aspect described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other aspects.

Although particular aspects are described herein, many variations and permutations of these aspects fall within the scope of the disclosure. Although some benefits and advantages of the preferred aspects are mentioned, the scope of the disclosure is not intended to be limited to particular benefits, uses or objectives. Rather, aspects of the disclosure are intended to be broadly applicable to different technologies, system configurations, networks and protocols, some of which are illustrated by way of example in the figures and in the following description of the preferred aspects. The detailed description and drawings are merely illustrative of the disclosure rather than limiting, the scope of the disclosure being defined by the appended claims and equivalents thereof.

An Example Neural System, Training and Operation

FIG. 1 illustrates an example artificial neural system 100 with multiple levels of neurons in accordance with certain aspects of the present disclosure. The neural system 100 may have a level of neurons 102 connected to another level of neurons 106 through a network of synaptic connections 104 (i.e., feed-forward connections). For simplicity, only two levels of neurons are illustrated in FIG. 1, although fewer or more levels of neurons may exist in a neural system. It should be noted that some of the neurons may connect to other neurons of the same layer through lateral connections. Furthermore, some of the neurons may connect back to a neuron of a previous layer through feedback connections.

As illustrated in FIG. 1, each neuron in the level 102 may receive an input signal 108 that may be generated by neurons of a previous level (not shown in FIG. 1). The signal 108 may represent an input current of the level 102 neuron. This current may be accumulated on the neuron membrane to charge a membrane potential. When the membrane potential reaches its threshold value, the neuron may fire and generate an output spike to be transferred to the next level of neurons (e.g., the level 106). In some modeling approaches, the neuron may continuously transfer a signal to the next level of neurons. This signal is typically a function of the membrane potential. Such behavior can be emulated or simulated in hardware and/or software, including analog and digital implementations such as those described below.

In biological neurons, the output spike generated when a neuron fires is referred to as an action potential. This electrical signal is a relatively rapid, transient, nerve impulse, having an amplitude of roughly 100 mV and a duration of about 1 ms. In a particular embodiment of a neural system having a series of connected neurons (e.g., the transfer of spikes from one level of neurons to another in FIG. 1), every action potential has basically the same amplitude and duration, and thus, the information in the signal may be represented only by the frequency and number of spikes, or the time of spikes, rather than by the amplitude. The information carried by an action potential may be determined by the spike, the neuron that spiked, and the time of the spike relative to other spike or spikes. The importance of the spike may be determined by a weight applied to a connection between neurons, as explained below.

The transfer of spikes from one level of neurons to another may be achieved through the network of synaptic connections (or simply “synapses”) 104, as illustrated in FIG. 1. Relative to the synapses 104, neurons of level 102 may be considered presynaptic neurons and neurons of level 106 may be considered postsynaptic neurons. The synapses 104 may receive output signals (i.e., spikes) from the level 102 neurons and (i scale those signals according to adjustable synaptic weights w₁ ^((i,i+1)), . . . , w_(P) ^((i,i+1)) where P is a total number of synaptic connections between the neurons of levels 102 and 106 and i is an indicator of the neuron level. In the example of FIG. 1, i represents neuron level 102 and i+1 represents neuron level 106. Further, the scaled signals may be combined as an input signal of each neuron in the level 106. Every neuron in the level 106 may generate output spikes 110 based on the corresponding combined input signal. The output spikes 110 may be transferred to another level of neurons using another network of synaptic connections (not shown in FIG. 1).

Biological synapses can mediate either excitatory or inhibitory (hyperpolarizing) actions in postsynaptic neurons and can also serve to amplify neuronal signals. Excitatory signals depolarize the membrane potential (i.e., increase the membrane potential with respect to the resting potential). If enough excitatory signals are received within a certain time period to depolarize the membrane potential above a threshold, an action potential occurs in the postsynaptic neuron. In contrast, inhibitory signals generally hyperpolarize (i.e., lower) the membrane potential. Inhibitory signals, if strong enough, can counteract the sum of excitatory signals and prevent the membrane potential from reaching a threshold. In addition to counteracting synaptic excitation, synaptic inhibition can exert powerful control over spontaneously active neurons. A spontaneously active neuron refers to a neuron that spikes without further input, for example due to its dynamics or a feedback. By suppressing the spontaneous generation of action potentials in these neurons, synaptic inhibition can shape the pattern of firing in a neuron, which is generally referred to as sculpturing. The various synapses 104 may act as any combination of excitatory or inhibitory synapses, depending on the behavior desired.

The neural system 100 may be emulated by a general purpose processor, a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) or other programmable logic device (PLD), discrete gate or transistor logic, discrete hardware components, a software module executed by a processor, or any combination thereof. The neural system 100 may be utilized in a large range of applications, such as image and pattern recognition, machine learning, motor control, and alike. Each neuron in the neural system 100 may be implemented as a neuron circuit. The neuron membrane charged to the threshold value initiating the output spike may be implemented, for example, as a capacitor that integrates an electrical current flowing through it.

In an aspect, the capacitor may be eliminated as the electrical current integrating device of the neuron circuit, and a smaller memristor element may be used in its place. This approach may be applied in neuron circuits, as well as in various other applications where bulky capacitors are utilized as electrical current integrators. In addition, each of the synapses 104 may be implemented based on a memristor element, where synaptic weight changes may relate to changes of the memristor resistance. With nanometer feature-sized memristors, the area of a neuron circuit and synapses may be substantially reduced, which may make implementation of a large-scale neural system hardware implementation more practical.

Functionality of a neural processor that emulates the neural system 100 may depend on weights of synaptic connections, which may control strengths of connections between neurons. The synaptic weights may be stored in a non-volatile memory in order to preserve functionality of the processor after being powered down. In an aspect, the synaptic weight memory may be implemented on a separate external chip from the main neural processor chip. The synaptic weight memory may be packaged separately from the neural processor chip as a replaceable memory card. This may provide diverse functionalities to the neural processor, where a particular functionality may be based on synaptic weights stored in a memory card currently attached to the neural processor.

FIG. 2 illustrates an exemplary diagram 200 of a processing unit (e.g., a neuron or neuron circuit) 202 of a computational network (e.g., a neural system or a neural network) in accordance with certain aspects of the present disclosure. For example, the neuron 202 may correspond to any of the neurons of levels 102 and 106 from FIG. 1. The neuron 202 may receive multiple input signals 204 ₁-204 _(N), which may be signals external to the neural system, or signals generated by other neurons of the same neural system, or both. The input signal may be a current, a conductance, a voltage, a real-valued, and/or a complex-valued. The input signal may comprise a numerical value with a fixed-point or a floating-point representation. These input signals may be delivered to the neuron 202 through synaptic connections that scale the signals according to adjustable synaptic weights 206 ₁-206 _(N) (W₁₋W_(N)), where N may be a total number of input connections of the neuron 202.

The neuron 202 may combine the scaled input signals and use the combined scaled inputs to generate an output signal 208 (i.e., a signal Y). The output signal 208 may be a current, a conductance, a voltage, a real-valued and/or a complex-valued. The output signal may be a numerical value with a fixed-point or a floating-point representation. The output signal 208 may be then transferred as an input signal to other neurons of the same neural system, or as an input signal to the same neuron 202, or as an output of the neural system.

The processing unit (neuron) 202 may be emulated by an electrical circuit, and its input and output connections may be emulated by electrical connections with synaptic circuits. The processing unit 202 and its input and output connections may also be emulated by a software code. The processing unit 202 may also be emulated by an electric circuit, whereas its input and output connections may be emulated by a software code. In an aspect, the processing unit 202 in the computational network may be an analog electrical circuit. In another aspect, the processing unit 202 may be a digital electrical circuit. In yet another aspect, the processing unit 202 may be a mixed-signal electrical circuit with both analog and digital components. The computational network may include processing units in any of the aforementioned forms. The computational network (neural system or neural network) using such processing units may be utilized in a large range of applications, such as image and pattern recognition, machine learning, motor control, and the like.

During the course of training a neural network, synaptic weights (e.g., the weights w₁ ^((i,i+1)), . . . , W_(P) ^((i,i+1)) from FIG. 1 and/or the weights 206 ₁-206 _(N) from FIG. 2) may be initialized with random values and increased or decreased according to a learning rule. Those skilled in the art will appreciate that examples of the learning rule include, but are not limited to the spike-timing-dependent plasticity (STDP) learning rule, the Hebb rule, the Oja rule, the Bienenstock-Copper-Munro (BCM) rule, etc. In certain aspects, the weights may settle or converge to one of two values (i.e., a bimodal distribution of weights). This effect can be utilized to reduce the number of bits for each synaptic weight, increase the speed of reading and writing from/to a memory storing the synaptic weights, and to reduce power and/or processor consumption of the synaptic memory.

Synapse Type

In hardware and software models of neural networks, the processing of synapse related functions can be based on synaptic type. Synapse types may be non-plastic synapses (no changes of weight and delay), plastic synapses (weight may change), structural delay plastic synapses (weight and delay may change), fully plastic synapses (weight, delay and connectivity may change), and variations thereupon (e.g., delay may change, but no change in weight or connectivity). The advantage of multiple types is that processing can be subdivided. For example, non-plastic synapses may not use plasticity functions to be executed (or waiting for such functions to complete). Similarly, delay and weight plasticity may be subdivided into operations that may operate together or separately, in sequence or in parallel. Different types of synapses may have different lookup tables or formulas and parameters for each of the different plasticity types that apply. Thus, the methods would access the relevant tables, formulas, or parameters for the synapse's type.

There are further implications of the fact that spike-timing dependent structural plasticity may be executed independently of synaptic plasticity. Structural plasticity may be executed even if there is no change to weight magnitude (e.g., if the weight has reached a minimum or maximum value, or it is not changed due to some other reason) s structural plasticity (i.e., an amount of delay change) may be a direct function of pre-post spike time difference. Alternatively, structural plasticity may be set as a function of the weight change amount or based on conditions relating to bounds of the weights or weight changes. For example, a synapse delay may change only when a weight change occurs or if weights reach zero but not if they are at a maximum value. However, it may be advantageous to have independent functions so that these processes can be parallelized reducing the number and overlap of memory accesses.

Determination of Synaptic Plasticity

Neuroplasticity (or simply “plasticity”) is the capacity of neurons and neural networks in the brain to change their synaptic connections and behavior in response to new information, sensory stimulation, development, damage, or dysfunction. Plasticity is important to learning and memory in biology, as well as for computational neuroscience and neural networks. Various forms of plasticity have been studied, such as synaptic plasticity (e.g., according to the Hebbian theory), spike-timing-dependent plasticity (STDP), non-synaptic plasticity, activity-dependent plasticity, structural plasticity and homeostatic plasticity.

STDP is a learning process that adjusts the strength of synaptic connections between neurons. The connection strengths are adjusted based on the relative timing of a particular neuron's output and received input spikes (i.e., action potentials). Under the STDP process, long-term potentiation (LTP) may occur if an input spike to a certain neuron tends, on average, to occur immediately before that neuron's output spike. Then, that particular input is made somewhat stronger. On the other hand, long-term depression (LTD) may occur if an input spike tends, on average, to occur immediately after an output spike. Then, that particular input is made somewhat weaker, and hence the name “spike-timing-dependent plasticity.” Consequently, inputs that might be the cause of the postsynaptic neuron's excitation are made even more likely to contribute in the future, whereas inputs that are not the cause of the postsynaptic spike are made less likely to contribute in the future. The process continues until a subset of the initial set of connections remains, while the influence of all others is reduced to an insignificant level.

Because a neuron generally produces an output spike when many of its inputs occur within a brief period (i.e., being cumulative sufficient to cause the output), the subset of inputs that typically remains includes those that tended to be correlated in time. In addition, because the inputs that occur before the output spike are strengthened, the inputs that provide the earliest sufficiently cumulative indication of correlation will eventually become the final input to the neuron.

The STDP learning rule may effectively adapt a synaptic weight of a synapse connecting a presynaptic neuron to a postsynaptic neuron as a function of time difference between spike time t_(pre) of the presynaptic neuron and spike time t_(post) of the postsynaptic neuron (i.e., t=t_(post)−t_(pre)). A typical formulation of the STDP is to increase the synaptic weight (i.e., potentiate the synapse) if the time difference is positive (the presynaptic neuron fires before the postsynaptic neuron), and decrease the synaptic weight (i.e., depress the synapse) if the time difference is negative (the postsynaptic neuron fires before the presynaptic neuron).

In the STDP process, a change of the synaptic weight over time may be typically achieved using an exponential decay, as given by:

$\begin{matrix} {{\Delta \; {w(t)}} = \left\{ {\begin{matrix} {{{a_{+}^{{- t}/k_{+}}} + \mu},} & {t > 0} \\ {{a_{-}^{t/k_{-}}},} & {t < 0} \end{matrix},} \right.} & (1) \end{matrix}$

where k₊ and k⁻τ_(sign(Δt)) are time constants for positive and negative time difference, respectively, α₊ and α⁻ are corresponding scaling magnitudes, and μ is an offset that may be applied to the positive time difference and/or the negative time difference.

FIG. 3 illustrates an exemplary diagram 300 of a synaptic weight change as a function of relative timing of presynaptic and postsynaptic spikes in accordance with the STDP. If a presynaptic neuron fires before a postsynaptic neuron, then a corresponding synaptic weight may be increased, as illustrated in a portion 302 of the graph 300. This weight increase can be referred to as an LTP of the synapse. It can be observed from the graph portion 302 that the amount of LTP may decrease roughly exponentially as a function of the difference between presynaptic and postsynaptic spike times. The reverse order of firing may reduce the synaptic weight, as illustrated in a portion 304 of the graph 300, causing an LTD of the synapse.

As illustrated in the graph 300 in FIG. 3, a negative offset μ may be applied to the LTP (causal) portion 302 of the STDP graph. A point of cross-over 306 of the x-axis (y=0) may be configured to coincide with the maximum time lag for considering correlation for causal inputs from layer i−1. In the case of a frame-based input (i.e., an input that is in the form of a frame of a particular duration comprising spikes or pulses), the offset value μ can be computed to reflect the frame boundary. A first input spike (pulse) in the frame may be considered to decay over time either as modeled by a postsynaptic potential directly or in terms of the effect on neural state. If a second input spike (pulse) in the frame is considered correlated or relevant to a particular time frame, then the relevant times before and after the frame may be separated at that time frame boundary and treated differently in plasticity terms by offsetting one or more parts of the STDP curve such that the value in the relevant times may be different (e.g., negative for greater than one frame and positive for less than one frame). For example, the negative offset μ may be set to offset LTP such that the curve actually goes below zero at a pre-post time greater than the frame time and it is thus part of LTD instead of LTP.

Neuron Models and Operation

There are some general principles for designing a useful spiking neuron model. A good neuron model may have rich potential behavior in terms of two computational regimes: coincidence detection and functional computation. Moreover, a good neuron model should have two elements to allow temporal coding: arrival time of inputs affects output time and coincidence detection can have a narrow time window. Finally, to be computationally attractive, a good neuron model may have a closed-form solution in continuous time and stable behavior including near attractors and saddle points. In other words, a useful neuron model is one that is practical and that can be used to model rich, realistic and biologically-consistent behaviors, as well as be used to both engineer and reverse engineer neural circuits.

A neuron model may depend on events, such as an input arrival, output spike or other event whether internal or external. To achieve a rich behavioral repertoire, a state machine that can exhibit complex behaviors may be desired. If the occurrence of an event itself, separate from the input contribution (if any), can influence the state machine and constrain dynamics subsequent to the event, then the future state of the system is not only a function of a state and input, but rather a function of a state, event, and input.

In an aspect, a neuron n may be modeled as a spiking leaky-integrate-and-fire neuron with a membrane voltage v_(n)(t) governed by the following dynamics:

$\begin{matrix} {{\frac{{v_{n}(t)}}{t} = {{\alpha \; {v_{n}(t)}} + {\beta {\sum\limits_{m}\; {w_{m,n}{y_{m}\left( {t - {\Delta \; t_{m,n}}} \right)}}}}}},} & (2) \end{matrix}$

where α and β are parameters, w_(m,n) is a synaptic weight for the synapse connecting a presynaptic neuron m to a postsynaptic neuron n, and y_(m) (t) is the spiking output of the neuron m that may be delayed by dendritic or axonal delay according to Δt_(m,n) until arrival at the neuron n's soma.

It should be noted that there is a delay from the time when sufficient input to a postsynaptic neuron is established until the time when the postsynaptic neuron actually fires. In a dynamic spiking neuron model, such as Izhikevich's simple model, a time delay may be incurred if there is a difference between a depolarization threshold v_(t) and a peak spike voltage v_(peak). For example, in the simple model, neuron soma dynamics can be governed by the pair of differential equations for voltage and recovery, i.e.:

$\begin{matrix} {{\frac{v}{t} = {\left( {{{k\left( {v - v_{t}} \right)}\left( {v - v_{r}} \right)} - u + I} \right)/C}},} & (3) \\ {{\frac{u}{t} = {a\left( {{b\left( {v - v_{r}} \right)} - u} \right)}},} & (4) \end{matrix}$

where v is a membrane potential, u is a membrane recovery variable, k is a parameter that describes time scale of the membrane potential v, a is a parameter that describes time scale of the recovery variable u, b is a parameter that describes sensitivity of the recovery variable u to the sub-threshold fluctuations of the membrane potential v, v_(r) is a membrane resting potential, I is a synaptic current, and C is a membrane's capacitance. In accordance with this model, the neuron is defined to spike when v>v_(peak).

Hunzinger Cold Model

The Hunzinger Cold neuron model is a minimal dual-regime spiking linear dynamical model that can reproduce a rich variety of neural behaviors. The model's one- or two-dimensional linear dynamics can have two regimes, wherein the time constant (and coupling) can depend on the regime. In the sub-threshold regime, the time constant, negative by convention, represents leaky channel dynamics generally acting to return a cell to rest in a biologically-consistent linear fashion. The time constant in the supra-threshold regime, positive by convention, reflects anti-leaky channel dynamics generally driving a cell to spike while incurring latency in spike-generation.

As illustrated in FIG. 4, the dynamics of the model 400 may be divided into two (or more) regimes. These regimes may be called the negative regime 402 (also interchangeably referred to as the leaky-integrate-and-fire (LIF) regime, not to be confused with the LIF neuron model) and the positive regime 404 (also interchangeably referred to as the anti-leaky-integrate-and-fire (ALIF) regime, not to be confused with the ALIF neuron model). In the negative regime 402, the state tends toward rest (v⁻) at the time of a future event. In this negative regime, the model generally exhibits temporal input detection properties and other sub-threshold behavior. In the positive regime 404, the state tends toward a spiking event (v_(s)). In this positive regime, the model exhibits computational properties, such as incurring a latency to spike depending on subsequent input events. Formulation of dynamics in terms of events and separation of the dynamics into these two regimes are fundamental characteristics of the model.

Linear dual-regime bi-dimensional dynamics (for states v and u) may be defined by convention as:

$\begin{matrix} {{\tau_{\rho}\frac{v}{t}} = {v + q_{\rho}}} & (5) \\ {{{{- \tau_{u}}\frac{u}{t}} = {u + r}},} & (6) \end{matrix}$

where q_(ρ) and r are the linear transformation variables for coupling.

The symbol ρ is used herein to denote the dynamics regime with the convention to replace the symbol ρ with the sign “−” or “+” for the negative and positive regimes, respectively, when discussing or expressing a relation for a specific regime.

The model state is defined by a membrane potential (voltage) v and recovery current u. In basic form, the regime is essentially determined by the model state. There are subtle, but important aspects of the precise and general definition, but for the moment, consider the model to be in the positive regime 404 if the voltage v is above a threshold (v₊) and otherwise in the negative regime 402.

The regime-dependent time constants include τ⁻ which is the negative regime time constant, and τ₊ which is the positive regime time constant. The recovery current time constant τ_(u) is typically independent of regime. For convenience, the negative regime time constant τ⁻ is typically specified as a negative quantity to reflect decay so that the same expression for voltage evolution may be used as for the positive regime in which the exponent and τ₊ will generally be positive, as will be τ_(u).

The dynamics of the two state elements may be coupled at events by transformations offsetting the states from their null-clines, where the transformation variables are:

q _(ρ) =−τβu−v _(ρ)  (7)

r=δ(v+ε),  (8)

where δ, ε, β and v⁻, v₊ are parameters. The two values for v_(ρ) are the base for reference voltages for the two regimes. The parameter v⁻ is the base voltage for the negative regime, and the membrane potential will generally decay toward v⁻ in the negative regime. The parameter v₊ is the base voltage for the positive regime, and the membrane potential will generally tend away from v₊ in the positive regime.

The null-clines for v and u are given by the negative of the transformation variables q_(ρ) and r, respectively. The parameter δ is a scale factor controlling the slope of the u null-cline. The parameter ε is typically set equal to −v⁻. The parameter β is a resistance value controlling the slope of the v null-clines in both regimes. The τ_(ρ) time-constant parameters control not only the exponential decays, but also the null-cline slopes in each regime separately.

The model may be defined to spike when the voltage v reaches a value v_(S). Subsequently, the state may be reset at a reset event (which may be one and the same as the spike event):

v={circumflex over (v)} ⁻  (9)

u=u+Δu,  (10)

where {circumflex over (v)}⁻ and Δu are parameters. The reset voltage {circumflex over (v)}⁻ is typically set to v⁻.

By a principle of momentary coupling, a closed form solution is possible not only for state (and with a single exponential term), but also for the time to reach a particular state. The close form state solutions are:

$\begin{matrix} {{v\left( {t + {\Delta \; t}} \right)} = {{\left( {{v(t)} + q_{\rho}} \right)^{\frac{\Delta \; t}{\tau_{\rho}}}} - q_{\rho}}} & (11) \\ {{u\left( {t + {\Delta \; t}} \right)} = {{\left( {{u(t)} + r} \right)^{- \frac{\Delta \; t}{\tau_{u}}}} - {r.}}} & (12) \end{matrix}$

Therefore, the model state may be updated only upon events, such as an input (presynaptic spike) or output (postsynaptic spike). Operations may also be performed at any particular time (whether or not there is input or output).

Moreover, by the momentary coupling principle, the time of a postsynaptic spike may be anticipated so the time to reach a particular state may be determined in advance without iterative techniques or Numerical Methods (e.g., the Euler numerical method). Given a prior voltage state v₀, the time delay until voltage state v_(f) is reached is given by:

$\begin{matrix} {{\Delta \; t} = {\tau_{\rho}\log {\frac{v_{f} + q_{\rho}}{v_{0} + q_{\rho}}.}}} & (13) \end{matrix}$

If a spike is defined as occurring at the time the voltage state v reaches v_(S), then the closed-form solution for the amount of time, or relative delay, until a spike occurs as measured from the time that the voltage is at a given state v is:

$\begin{matrix} {{\Delta \; t_{s}} = \left\{ \begin{matrix} {\tau_{+}\log \frac{v_{s} + q_{+}}{v + q_{+}}} & {{{if}\mspace{14mu} v} > {\hat{v}}_{+}} \\ \infty & {otherwise} \end{matrix} \right.} & (14) \end{matrix}$

where {circumflex over (v)}₊ is typically set to parameter v₊, although other variations may be possible.

The above definitions of the model dynamics depend on whether the model is in the positive or negative regime. As mentioned, the coupling and the regime ρ may be computed upon events. For purposes of state propagation, the regime and coupling (transformation) variables may be defined based on the state at the time of the last (prior) event. For purposes of subsequently anticipating spike output time, the regime and coupling variable may be defined based on the state at the time of the next (current) event.

There are several possible implementations of the Cold model, and executing the simulation, emulation or model in time. This includes, for example, event-update, step-event update, and step-update modes. An event update is an update where states are updated based on events or “event update” (at particular moments). A step update is an update when the model is updated at intervals (e.g., 1 ms). This does not necessarily utilize iterative methods or Numerical methods. An event-based implementation is also possible at a limited time resolution in a step-based simulator by only updating the model if an event occurs at or between steps or by “step-event” update.

Decomposing Convolution Operation in Neural Networks

Deep Convolution Networks (DCNs) are widely used in many Computer Vision applications including Object Classification, Object Localization, Face Recognition and Scene Recognition. Convolution operations are one of the most computationally intensive blocks in DCNs. Aspects of the present disclosure are directed to methods to reduce the computational complexity of the convolution operation by expressing the two dimensional (2-D) convolution operation as a composition of 1-D convolution operations in DCNs.

A convolution operation may be understood on one dimensional (1-D) arrays. An input vector X of length N may be convolved with a filter W of length A to produce an output vector Y=X*W of length N−M+1:

y _(k)=Σ_(i=0) ^(M−1) x _(k+i) w _(i) , k=0,1, . . . ,N−M,  (15)

where M and N are integer values.

Ignoring additions, the computational complexity may be expressed in terms of the number of multiplications. The number of multiplications in the above operation is equal to (N−M)*M. Assuming that the filter size is smaller in comparison to input size, the number of multiplications is of the order of O(NM) multiplications using big-O notation.

In Deep Convolution Networks, the convolution operation may be performed on 2-D matrices instead of 1-D vectors. For example, an input matrix X of dimensions N₁×N₂ may be convolved with a filter matrix W of dimensions M₁×M₂ to produce an output matrix Y of dimensions (N₁−M₁+1)×(N₂−M₂+1) as follows:

$\begin{matrix} {{y_{k,l} = {\sum\limits_{i = 0}^{M_{1} - 1}\; {\sum\limits_{j = 0}^{M_{2} - 1}\; {x_{{k + i},{l + j}}w_{i,j}}}}},{k = 0},1,\ldots \mspace{14mu},{N_{1} - M_{1}},{l = 0},1,\ldots \mspace{14mu},{N_{2} - {M_{2}.}}} & (16) \end{matrix}$

The computational complexity may be on the order of O(N₁N₂M₁M₂) multiplications. If the matrices are square, i.e., N₁=N₂=N and M₁=M₂=M, then the computational complexity is of the order of O(N²M²).

Decomposing 2-D Convolution Operation

Depending on the rank of the filter matrix W, the 2-D convolution operation may be expressed as a composition of 1-D convolution operations. For example, the filter matrix W may be expressed as a linear combination of rank one matrices using Singular Value Decomposition (SVD):

$\begin{matrix} {W = {\sum\limits_{r = 1}^{{rank}{(W)}}\; {W_{r}.}}} & (17) \end{matrix}$

In this example, rank(W) denotes the rank of the matrix W, and the matrices W₁, W₂, . . . , W_(rank(W)) are all unit rank matrices. Further, each of the unit rank matrices may be expressed as a product of a column vector times a row vector.

The 2-D convolution operation with filter matrix W may be decomposed as a linear combination of 2-D convolution operations with unit rank matrices. The advantage of 2-D convolution operation with a unit rank matrix is that the operation may be decomposed into two 1-D convolution operations.

In one example, suppose W_(i)=U_(i)V_(i) ^(T) where U_(i) is a column vector and V_(i) ^(T) is a row vector. Then the 2-D convolution operation X*W_(i) may be decomposed by first convolving each column of matrix X with the column vector U_(i) and then convolving each row of the resulting matrix with the row vector V_(i) ^(T).

This method of computing 2-D convolution with a unit rank matrix using two 1-D convolutions has a computational complexity:

N ₂ O(N ₁ M ₁)+N ₁ O(N ₂ M ₂)=O(N ₁ N ₂(M ₁ +M ₂)).

Because the column and row convolution operations are repeated for each of the unit rank matrices, the overall computational complexity of this approach may be expressed as:

O(rank(W)N ₁ N ₂(M ₁ +M ₂)).

In the case of square matrices, this is equal to O(2rank(W)N²M). This is in comparison with O(N²M²), which is the computational complexity of a 2-D convolution operation.

The decomposition method may be efficient if the filter matrix W has a small rank (rank(W)) and has larger dimensionality (M). For instance, consider the example where the filter matrix is of size 16×16 and has a rank of 2, then O(2*2*16*N²)≦O(64N²) multiplications using the decomposition method is compared to O(256N²) multiplications using the traditional method. If the filter matrix W had a unit rank, then the comparison is between O(32N²) multiplications and O(256N²) multiplications.

In accordance with aspects of the present disclosure, the method of decomposing 2-D convolution operations into 1-D convolution operations may be applied to DCNs in the following ways:

In one aspect, a DCN may be trained using any training technique. At the end of training, a rank of the filter matrices may be computed. It can be determined whether to implement the 2-D convolution operation using the decomposition method by comparing O(N₁N₂M₁M₂) to O(rank(W)N₁N₂(M₁+M₂)).

In some aspects, the DCN may be subjected to pre-processing such that filter matrices may be replaced by a low rank approximation. The filter weight matrix may be approximated using only the top few unit rank matrices:

$\begin{matrix} {W \approx {\sum\limits_{r = 1}^{R}\; {{UV}_{r}^{T}.}}} & (18) \end{matrix}$

Here, R can be as small as one, or can be selected based on the energy distribution of the singular values. Typically, most of the energy is concentrated in the top few singular values. In some aspects, R may be empirically chosen. For example, R may be chosen based on the overall classification performance of the DCN by trying different values for R. That is, the final value of R may be determined according to computing accuracy on a validation dataset for different values of R. The lowest value of R with negligible performance degradation may be selected.

After the low rank approximation, a pre-trained classifier may be used or the classifier may be re-trained.

In another aspect, the training process may be encouraged to converge to unit rank or low rank filter weight matrices. A filter may be deemed to have a low rank if the rank<K/2, where K is the size of the filter weight matrix, for example. Another example of a low rank filter is a Gabor filter which may be expressed as follows:

$\begin{matrix} {W_{xy} = {{\exp \left( {- \frac{x^{2} + y^{2}}{2\sigma^{2}}} \right)}{{\cos \left( {2\pi \; {f\left( {{x\; \cos \; \theta} + {y\; \sin \; \theta}} \right)}} \right)}.}}} & (19) \end{matrix}$

The Gabor filter matrix has a rank of one and is therefore separable if θ=0, 90, 180, or 270. On the other hand, the rank of the Gabor filter is two for all other values of θ. In this case, the Gabor filter is the sum of two separable filters.

In one exemplary aspect, the unit or low rank filter matrices may be encouraged by adding a regularizer term (e.g., cost function) to the objective function so as to penalize high rank matrices. For example, a nuclear norm may be used to reduce the rank. The nuclear norm is the sum of singular values and may be expressed as:

∥W∥ _(*)=Σσ_(i)=trace(√{square root over (W ^(T) W)}),  (20)

where σ_(i) are the singular values and λ∥W∥_(*) is added to the objective function for each filter, where λ is the cost function. Accordingly, a weight decay term of

${- \lambda}\frac{\partial{W}_{*}}{\partial w_{ij}}$

is added to the gradient update equation. Of course, other regularizers may also be used to reduce the filter rank. Having reduced the filter rank, the decomposed convolution may be applied.

In another exemplary aspect, a certain rank for the filter weight matrices (e.g., unit or low rank) may be enforced, and back propagation (or equivalently gradient descent) may be applied to compute updates on these enforced matrices.

For example, suppose the filter matrix is forced to be of unit rank. Then W takes the form of UV^(T), where U is a column vector and V is a row vector. The elements w_(ij) may not be free variables, but instead may be derived variables based on the free variables u_(i) and v_(j):

w _(ij) =u _(i) v _(j).  (21)

A back propagation process may be applied to compute the partial gradients with respect to the elements w_(ij). The partial gradients with respect to the elements w_(ij) may, in turn, be used to compute the partial gradients with respect to the free variables u_(i) and v_(j) in the following way:

$\begin{matrix} {\frac{\partial L}{\partial u_{i}} = {{\Sigma_{j}\frac{\partial L}{\partial w_{ij}}\frac{\partial w_{ij}}{\partial u_{i}}} = {\Sigma_{j}\frac{\partial L}{\partial w_{ij}}v_{j}}}} & (22) \\ {\frac{\partial L}{\partial v_{j}} = {{\Sigma_{i}\frac{\partial L}{\partial w_{ij}}\frac{\partial w_{ij}}{\partial v_{j}}} = {\Sigma_{i}\frac{\partial L}{\partial w_{ij}}u_{i}}}} & (23) \end{matrix}$

where L represents the loss (or objective) function that is being reduced. These partial gradients may be used to update the variables u_(i) and v_(j) and essentially perform a gradient descendent in the space of unit rank weight matrices. Thus, the resulting trained DCN will have unit rank matrices and the decomposition method may be employed to efficiently implement the convolution operations.

In another exemplary aspect, an arbitrary rank (r) on the filter matrices maybe enforced instead of enforcing the filter matrices to be of unit rank. The back propagation process to compute the partial gradients may be performed to determine updates for variables u_(i) and v_(j), as discussed above.

In some aspects, the same weight updates for each of the contributing unit rank matrices and a random initial condition for diversity may be used. In another aspect, an additional constraint that the r column vectors are orthogonal to each other and the r row vectors are orthogonal to each other may be used to encourage diversity.

In some aspects, it may be desirable to reuse separable filters. For example, where a DCN has a number of filters operating on the same input, it may be beneficial to encourage reuse of the underlying filters. This may be achieved by configuring a bank of L separable filters U₁V₁ ^(T), U₂V₂ ^(T), . . . U_(L)V_(L) ^(T). Each filter may be constrained to be a linear combination of a random subset of size R of the underlying filters:

$\begin{matrix} {{W_{p} = {\sum\limits_{r \in S_{p}}\; {\alpha_{pr}U_{r}V_{r}^{T}}}},} & (24) \end{matrix}$

where S_(p) is the subset of separable filters used by filter p and α_(pr) is a linear combination parameter. Back propagation may be applied to learn the L separable filters and the linear combination parameter.

FIG. 5 illustrates an example implementation 500 of the aforementioned decomposition using a general-purpose processor 502 in accordance with certain aspects of the present disclosure. Variables (neural signals), synaptic weights, system parameters associated with a computational network (neural network), delays, and frequency bin information may be stored in a memory block 504, while instructions executed at the general-purpose processor 502 may be loaded from a program memory 506. In an aspect of the present disclosure, the instructions loaded into the general-purpose processor 502 may comprise code for determining a number of separable filters to express a filter in the neural network and/or selectively applying a decomposed convolution to the filter.

In another aspect of the present disclosure, the instructions loaded into the general-purpose processor 502 may comprise code for encouraging one or more filters in the neural network to have a low rank.

FIG. 6 illustrates an example implementation 600 of the aforementioned decomposition techniques where a memory 602 can be interfaced via an interconnection network 604 with individual (distributed) processing units (neural processors) 606 of a computational network (neural network) in accordance with certain aspects of the present disclosure. Variables (neural signals), synaptic weights, system parameters associated with the computational network (neural network) delays, frequency bin information, regularization information and/or system metrics may be stored in the memory 602, and may be loaded from the memory 602 via connection(s) of the interconnection network 604 into each processing unit (neural processor) 606. In an aspect of the present disclosure, the processing unit 606 may be configured to determine a number of separable filters to express a filter in the neural network and/or selectively apply a decomposed convolution to the filter.

In another aspect of the present disclosure, the processing unit 606 may be configured to encourage one or more filters in the neural network to have a low rank.

FIG. 7 illustrates an example implementation 700 of the aforementioned decomposition. As illustrated in FIG. 7, one memory bank 702 may be directly interfaced with one processing unit 704 of a computational network (neural network). Each memory bank 702 may store variables (neural signals), synaptic weights, and/or system parameters associated with a corresponding processing unit (neural processor) 704 delays, frequency bin information, regularization information and/or system metrics. In an aspect of the present disclosure, the processing unit 704 may be configured to determine a number of separable filters to express a filter in the neural network and/or selectively apply a decomposed convolution to the filter.

In another aspect of the present disclosure, the processing unit 704 may be configured to encourage one or more filters in the neural network to have a low rank.

FIG. 8 illustrates an example implementation of a neural network 800 in accordance with certain aspects of the present disclosure. As illustrated in FIG. 8, the neural network 800 may have multiple local processing units 802 that may perform various operations of methods described herein. Each local processing unit 802 may comprise a local state memory 804 and a local parameter memory 806 that store parameters of the neural network. In addition, the local processing unit 802 may have a local (neuron) model program (LMP) memory 808 for storing a local model program, a local learning program (LLP) memory 810 for storing a local learning program, and a local connection memory 812. Furthermore, as illustrated in FIG. 8, each local processing unit 802 may be interfaced with a configuration processor unit 814 for providing configurations for local memories of the local processing unit, and with a routing connection processing unit 816 that provide routing between the local processing units 802.

In one configuration, a neuron model is configured for determining a number of separable filters to express a filter in the neural network and selectively applying a decomposed convolution to the filter. The neuron model includes determining means and applying means. In one aspect, the determining means and/or applying means may be the general-purpose processor 502, program memory 506, memory block 504, memory 602, interconnection network 604, processing units 606, processing unit 704, local processing units 802, and or the routing connection processing units 816 configured to perform the functions recited. In another configuration, the aforementioned means may be any module or any apparatus configured to perform the functions recited by the aforementioned means.

In another configuration, a neuron model is configured for encouraging one or more filters in the neural network to have a low rank and applying a decomposed convolution to the filter(s) to train the neural network. The neuron model includes encouraging means and applying means. In one aspect, the encouraging means and/or applying means may be the general-purpose processor 502, program memory 506, memory block 504, memory 602, interconnection network 604, processing units 606, processing unit 704, local processing units 802, and or the routing connection processing units 816 configured to perform the functions recited. In another configuration, the aforementioned means may be any module or any apparatus configured to perform the functions recited by the aforementioned means.

According to certain aspects of the present disclosure, each local processing unit 802 may be configured to determine parameters of the neural network based upon desired one or more functional features of the neural network, and develop the one or more functional features towards the desired functional features as the determined parameters are further adapted, tuned and updated.

FIG. 9 illustrates a method 900 for operating a neural network. In block 902, the process determines a complexity of separable filters approximating a filter. For example, the process may determine a number of separable filters that are sufficient to express or approximate a filter in the neural network. Rather than determining a number of separable filters, computational complexity may be assessed. In some aspects, the determination of the number of separable filters may be based on the rank of the filter. In other aspects, the determination of the number of separable filters may be based on singular value decomposition (SVD) of the filter.

In block 904, the process may also selectively apply a decomposed convolution to the filter, for example based on the complexity.

In some aspects, the neuron model may further replace the filter with a low rank approximation. The replacement may be based on a performance metric, for example. In some aspects, the replacement may be based on singular values obtained by computing a single value decomposition.

FIG. 10 illustrates a method 1000 of training a neural network. In block 1002, the neuron model encourages one or more filters in the neural network to have a low rank. In some aspects, the neuron model encourages filter(s) to have low rank by applying a regularizer to a filter weight matrix of the filter(s). The regularizer may comprise a cost metric or a nuclear norm, for example. The filter can be encouraged to have a low rank by adding a regularizer term to an optimization criterion used in a back propagation (or gradient descent) training algorithm. The addition of such regularizer term changes the gradient update equations. In other words, during training, filter weights are updated using these gradients update terms. Optionally, in block 1004, the neuron model applies a decomposed convolution to the filter(s) to train the neural network. Such decomposition can occur during inference, especially when the filter(s) is low rank.

In some aspects, the neuron model encourages filter(s) to have low rank by dividing the filter into a linear combination of the row filters and column filters. The neuron model may further apply a gradient update learned by back propagation to learn the row filters and the column filters.

The various operations of methods described above may be performed by any suitable means capable of performing the corresponding functions. The means may include various hardware and/or software component(s) and/or module(s), including, but not limited to, a circuit, an application specific integrated circuit (ASIC), or processor. Generally, where there are operations illustrated in the figures, those operations may have corresponding counterpart means-plus-function components with similar numbering.

As used herein, the term “determining” encompasses a wide variety of actions. For example, “determining” may include calculating, computing, processing, deriving, investigating, looking up (e.g., looking up in a table, a database or another data structure), ascertaining and the like. Additionally, “determining” may include receiving (e.g., receiving information), accessing (e.g., accessing data in a memory) and the like. Furthermore, “determining” may include resolving, selecting, choosing, establishing and the like.

As used herein, a phrase referring to “at least one of” a list of items refers to any combination of those items, including single members. As an example, “at least one of: a, b, or c” is intended to cover: a, b, c, a-b, a-c, b-c, and a-b-c.

The various illustrative logical blocks, modules and circuits described in connection with the present disclosure may be implemented or performed with a general purpose processor, a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable gate array signal (FPGA) or other programmable logic device (PLD), discrete gate or transistor logic, discrete hardware components or any combination thereof designed to perform the functions described herein. A general-purpose processor may be a microprocessor, but in the alternative, the processor may be any commercially available processor, controller, microcontroller or state machine. A processor may also be implemented as a combination of computing devices, e.g., a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration.

The steps of a method or algorithm described in connection with the present disclosure may be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two. A software module may reside in any form of storage medium that is known in the art. Some examples of storage media that may be used include random access memory (RAM), read only memory (ROM), flash memory, erasable programmable read-only memory (EPROM), electrically erasable programmable read-only memory (EEPROM), registers, a hard disk, a removable disk, a CD-ROM and so forth. A software module may comprise a single instruction, or many instructions, and may be distributed over several different code segments, among different programs, and across multiple storage media. A storage medium may be coupled to a processor such that the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor.

The methods disclosed herein comprise one or more steps or actions for achieving the described method. The method steps and/or actions may be interchanged with one another without departing from the scope of the claims. In other words, unless a specific order of steps or actions is specified, the order and/or use of specific steps and/or actions may be modified without departing from the scope of the claims.

The functions described herein may be implemented in hardware, software, firmware, or any combination thereof. If implemented in hardware, an example hardware configuration may comprise a processing system in a device. The processing system may be implemented with a bus architecture. The bus may include any number of interconnecting buses and bridges depending on the specific application of the processing system and the overall design constraints. The bus may link together various circuits including a processor, machine-readable media, and a bus interface. The bus interface may be used to connect a network adapter, among other things, to the processing system via the bus. The network adapter may be used to implement signal processing functions. For certain aspects, a user interface (e.g., keypad, display, mouse, joystick, etc.) may also be connected to the bus. The bus may also link various other circuits such as timing sources, peripherals, voltage regulators, power management circuits, and the like, which are well known in the art, and therefore, will not be described any further.

The processor may be responsible for managing the bus and general processing, including the execution of software stored on the machine-readable media. The processor may be implemented with one or more general-purpose and/or special-purpose processors. Examples include microprocessors, microcontrollers, DSP processors, and other circuitry that can execute software. Software shall be construed broadly to mean instructions, data, or any combination thereof, whether referred to as software, firmware, middleware, microcode, hardware description language, or otherwise. Machine-readable media may include, by way of example, random access memory (RAM), flash memory, read only memory (ROM), programmable read-only memory (PROM), erasable programmable read-only memory (EPROM), electrically erasable programmable Read-only memory (EEPROM), registers, magnetic disks, optical disks, hard drives, or any other suitable storage medium, or any combination thereof. The machine-readable media may be embodied in a computer-program product. The computer-program product may comprise packaging materials.

In a hardware implementation, the machine-readable media may be part of the processing system separate from the processor. However, as those skilled in the art will readily appreciate, the machine-readable media, or any portion thereof, may be external to the processing system. By way of example, the machine-readable media may include a transmission line, a carrier wave modulated by data, and/or a computer product separate from the device, all which may be accessed by the processor through the bus interface. Alternatively, or in addition, the machine-readable media, or any portion thereof, may be integrated into the processor, such as the case may be with cache and/or general register files. Although the various components discussed may be described as having a specific location, such as a local component, they may also be configured in various ways, such as certain components being configured as part of a distributed computing system.

The processing system may be configured as a general-purpose processing system with one or more microprocessors providing the processor functionality and external memory providing at least a portion of the machine-readable media, all linked together with other supporting circuitry through an external bus architecture. Alternatively, the processing system may comprise one or more neuromorphic processors for implementing the neuron models and models of neural systems described herein. As another alternative, the processing system may be implemented with an application specific integrated circuit (ASIC) with the processor, the bus interface, the user interface, supporting circuitry, and at least a portion of the machine-readable media integrated into a single chip, or with one or more field programmable gate arrays (FPGAs), programmable logic devices (PLDs), controllers, state machines, gated logic, discrete hardware components, or any other suitable circuitry, or any combination of circuits that can perform the various functionality described throughout this disclosure. Those skilled in the art will recognize how best to implement the described functionality for the processing system depending on the particular application and the overall design constraints imposed on the overall system.

The machine-readable media may comprise a number of software modules. The software modules include instructions that, when executed by the processor, cause the processing system to perform various functions. The software modules may include a transmission module and a receiving module. Each software module may reside in a single storage device or be distributed across multiple storage devices. By way of example, a software module may be loaded into RAM from a hard drive when a triggering event occurs. During execution of the software module, the processor may load some of the instructions into cache to increase access speed. One or more cache lines may then be loaded into a general register file for execution by the processor. When referring to the functionality of a software module below, it will be understood that such functionality is implemented by the processor when executing instructions from that software module.

If implemented in software, the functions may be stored or transmitted over as one or more instructions or code on a computer-readable medium. Computer-readable media include both computer storage media and communication media including any medium that facilitates transfer of a computer program from one place to another. A storage medium may be any available medium that can be accessed by a computer. By way of example, and not limitation, such computer-readable media can comprise RAM, ROM, EEPROM, CD-ROM or other optical disk storage, magnetic disk storage or other magnetic storage devices, or any other medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer. In addition, any connection is properly termed a computer-readable medium. For example, if the software is transmitted from a website, server, or other remote source using a coaxial cable, fiber optic cable, twisted pair, digital subscriber line (DSL), or wireless technologies such as infrared (IR), radio, and microwave, then the coaxial cable, fiber optic cable, twisted pair, DSL, or wireless technologies such as infrared, radio, and microwave are included in the definition of medium. Disk and disc, as used herein, include compact disc (CD), laser disc, optical disc, digital versatile disc (DVD), floppy disk, and Blu-ray® disc where disks usually reproduce data magnetically, while discs reproduce data optically with lasers. Thus, in some aspects computer-readable media may comprise non-transitory computer-readable media (e.g., tangible media). In addition, for other aspects computer-readable media may comprise transitory computer-readable media (e.g., a signal). Combinations of the above should also be included within the scope of computer-readable media.

Thus, certain aspects may comprise a computer program product for performing the operations presented herein. For example, such a computer program product may comprise a computer-readable medium having instructions stored (and/or encoded) thereon, the instructions being executable by one or more processors to perform the operations described herein. For certain aspects, the computer program product may include packaging material.

Further, it should be appreciated that modules and/or other appropriate means for performing the methods and techniques described herein can be downloaded and/or otherwise obtained by a user terminal and/or base station as applicable. For example, such a device can be coupled to a server to facilitate the transfer of means for performing the methods described herein. Alternatively, various methods described herein can be provided via storage means (e.g., RAM, ROM, a physical storage medium such as a compact disc (CD) or floppy disk, etc.), such that a user terminal and/or base station can obtain the various methods upon coupling or providing the storage means to the device. Moreover, any other suitable technique for providing the methods and techniques described herein to a device can be utilized.

It is to be understood that the claims are not limited to the precise configuration and components illustrated above. Various modifications, changes and variations may be made in the arrangement, operation and details of the methods and apparatus described above without departing from the scope of the claims. 

What is claimed is:
 1. A method of operating a neural network, comprising: determining a complexity of separable filters approximating a filter in the neural network; and selectively applying a decomposed convolution to the filter based at least in part on the determining.
 2. The method of claim 1, in which the determining is based at least in part on a rank of the filter.
 3. The method of claim 1, further comprising: replacing the filter with a low rank approximation based at least in part on a performance metric.
 4. The method of claim 1, in which the determining is based at least in part on a singular value decomposition (SVD) of the filter.
 5. The method of claim 4, further comprising: replacing the filter with a low rank approximation based at least in part on singular values obtained via the singular value decomposition.
 6. The method of claim 1, in which the determined complexity comprises a number of separable filters sufficient to approximate the filter.
 7. An apparatus for operating a neural network, comprising: a memory; and at least one processor coupled to the memory, the at least one processor being configured: to determine a complexity of separable filters approximating a filter in the neural network; and to selectively apply a decomposed convolution to the filter based at least in part on the determined complexity of separable filters.
 8. The apparatus of claim 7, in which the at least one processor is further configured to determine the complexity of separable filters based at least in part on a rank of the filter.
 9. The apparatus of claim 7, in which the at least one processor is further configured to replace the filter with a low rank approximation based at least in part on a performance metric.
 10. The apparatus of claim 7, the at least one processor is further configured to determine the complexity of separable filters based at least in part on a singular value decomposition (SVD) of the filter.
 11. The apparatus of claim 10, in which the at least one processor is further configured to replace the filter with a low rank approximation based at least in part on singular values obtained via the singular value decomposition.
 12. The apparatus of claim 7, in which the determined complexity comprises a number of separable filters sufficient to approximate the filter.
 13. An apparatus for operating a neural network, comprising: means for determining a complexity of separable filters approximating a filter in the neural network; and means for selectively applying a decomposed convolution to the filter based at least in part on the determined complexity of separable filters.
 14. The apparatus of claim 13, in which the determined complexity of separable filters is based at least in part on a rank of the filter.
 15. The apparatus of claim 13, further comprising: means for replacing the filter with a low rank approximation based at least in part on a performance metric.
 16. The apparatus of claim 13, in which the determined complexity of separable filters is based at least in part on a singular value decomposition (SVD) of the filter.
 17. The apparatus of claim 16, further comprising: means for replacing the filter with a low rank approximation based at least in part on singular values obtained via the singular value decomposition.
 18. A computer program product for operating a neural network, comprising: a non-transitory computer readable medium having encoded thereon program code, the program code comprising: program code to determine a complexity of separable filters approximating a filter in the neural network; and program code to selectively apply a decomposed convolution to the filter based at least in part on the determined complexity of separable filters.
 19. The computer program product of claim 18, further comprising program code to determine the complexity of separable filters based at least in part on a rank of the filter.
 20. The computer program product of claim 18, further comprising program code to replace the filter with a low rank approximation based at least in part on a performance metric.
 21. The computer program product of claim 18, further comprising program code to determine the complexity of separable filters based at least in part on a singular value decomposition (SVD) of the filter.
 22. The computer program product of claim 21, further comprising program code to replace the filter with a low rank approximation based at least in part on singular values obtained via the singular value decomposition. 